Abstract
There are still many challenges to overcome for human space exploration beyond low Earth orbit (LEO) (e.g., to the Moon) and for long-term missions (e.g., to Mars). One of the biggest problems is the reliable air, water and food supply for the crew. Bioregenerative life support systems (BLSS) aim to overcome these challenges using bioreactors for waste treatment, air and water revitalization as well as food production. In this review we focus on the microbial photosynthetic bioprocess and photobioreactors in space, which allow removal of toxic carbon dioxide (CO2) and production of oxygen (O2) and edible biomass. This paper gives an overview of the conducted space experiments in LEO with photobioreactors and the precursor work (on ground and in space) for BLSS projects over the last 30 years. We discuss the different hardware approaches as well as the organisms tested for these bioreactors. Even though a lot of experiments showed successful biological air revitalization on ground, the transfer to the space environment is far from trivial. For example, gas-liquid transfer phenomena are different under microgravity conditions which inevitably can affect the cultivation process and the oxygen production. In this review, we also highlight the missing expertise in this research field to pave the way for future space photobioreactor development and we point to future experiments needed to master the challenge of a fully functional BLSS.
Highlights
Human space exploration aims to go farther into space and crewed missions are planned to Moon and Mars
This challenge can be solved by the development of a bioregenerative life support system (BLSS), Photobioreactors in Space that meets the needs at least for a part of food supply to the crew and secures air, water as well as safe waste recycling (Gitelson et al, 1976)
This review will focus on the bioprocess of microbial photosynthesis and, in particular, on photobioreactors (PBRs) used in space for BLSS
Summary
In order to minimize the resupply needs and the embarked mass, the recycling process will have to include food production coupled to oxygen (O2) and water (H2O) recovery that entails the use of at least one biological compartment for producing edible biomass. This challenge can be solved by the development of a bioregenerative life support system (BLSS), Photobioreactors in Space that meets the needs at least for a part of food supply to the crew and secures air, water as well as safe waste recycling (Gitelson et al, 1976). The following sections describe the general requirements for life support systems and the current state of the art to how a BLSS can be developed using different techniques and organisms
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